Omnidirectional communication device

ABSTRACT

An omnidirectional communication device includes a central core to transmit a signal. The device includes inductor coils surrounding the central core to generate electromagnetic fields within and impart gyroscopic spin to the central core. The device includes high voltage coils to generate a plasma field within which the central core and the inductor coils rotate. The device includes a signal injection circuit to introduce the signal into the device in accordance with data to be transmitted. Rotation of the central core and the inductor coils within the plasma field warp the signal, causing the central core to transmit the signal outside of the device.

RELATED APPLICATIONS

This application claims priority to the provisional patent application filed on Apr. 26, 2021, and assigned provisional patent app. No. 63/179,664.

BACKGROUND

Communication devices permit data to be transmitted and received at different locations. For example, a transmitter device may transmit data at one location, which a receiver device receives at another location. A communication device may be able to function as both a transmitter device and a receiver device, so that it can both send and receive communication from another device. A communication device may be communicatively connected to a host computing device that provides the data to be transmitted by the communication device, and that receives the data that has been received by the communication.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a front view diagram of an example omnidirectional communication device.

FIG. 2 is a top view diagram of the example omnidirectional communication device of FIG. 1, in which the high voltage coils and the inductor coils are depicted in detail.

FIG. 3 is a diagram of an example central core of the omnidirectional communication device of FIG. 1

DETAILED DESCRIPTION

FIG. 1 shows a front view of an example omnidirectional communication device 100. The communication device 100 includes a central core 102, inductor coils 104, and high voltage coils 106. In the depicted example, the high voltage coils 106 can be cylindrical, whereas the inductor coils 104 can be ring, loop, or toroidal in shape, although they can also be spherical. The top and bottom of the device 100 may be or include radio frequency coils (i.e., loop antennas), such as Helmholtz coils but which also can produce signal throughout the device. Helmholtz coils can also be implemented externally to measure magnetic field.

The communication device 100 further includes a signal injection circuit 108 in an implementation in which the device 100 is to transmit a signal in accordance with data that may be encrypted or unencrypted. The communication device 100 can in addition or instead include a signal detector circuit 110 in an implementation in which the device 100 is to receive a signal that has been transmitted in accordance with data that may be encrypted or decrypted. The device 100 therefore can include either or both of the circuits 108 and 110. The circuits 108 and 110 are depicted in block form, but in actuality may be located on the sides and/or the top and bottom of the device 100. The circuits 108 and 110 may be directly mounted around the device 100 or mounted to a removable or permanent spherical or toroidal cavity resonator, such as shell resonator, and pointed at the central core 102 of the device 110. Further, the device 100 may function as a radio repeater.

Either or both of the circuits 108 and 110 can be or include one or multiple devices that work together. For example, the detector circuit 110 may be one or multiple devices that work together to receive or intercept a signal from inside and/or outside the device. Examples of such a detector circuit 110 include silicon avalanche diodes, photodiodes, laser diodes, scintillators, antennas, photodetectors, magnetometers, photomultiplier tubes, flat-panel detectors, microchannel plate detector, magnetic pickups, inductive sensors, resonant coils antennas, image sensors, optical sensors, and transducers. Furthermore, the signal injection circuit 108 may receive data from modems, oscillators, antennas, fiber optic cables and/or satellites.

The high voltage coils 106 generates a plasma field within which the central core 102 and the inductor coils 104 rotate. In another implementation, the high voltage coils 106 may be removed, to utilize just the inductor coils 104 and the central core 102 in an open system having zero confinement or traps, in which case magnetic confinement and/or homogeneous magnetic fields may be used as traps. The inductor coils 104 surround the central core 102. The inductor coils 104 generate electromagnetic fields within and impart gyroscopic spin to the central core 102.

In the case of signal transmission, the signal injection circuit 108 introduces a signal into the omnidirectional communication device 100 in accordance with data to be transmitted. That is, the signal represents the data to be transmitted, such as via the data being encoded within the signal. Rotation of the central core 102 and the inductor coils 104 within the plasma field warp the signal. This causes the central core 102 to omnidirectionally transmit the signal outside the communication device 100.

In the case of signal receipt, the central core 102 receives an omnidirectionally signal transmitted from outside of the communication device 100 in accordance with data. That is, the signal represents data, such as via the data being encoded within the signal. Rotation of the central core 102 and the inductor coils 104 within the plasma field warp the signal. The signal detector circuit 110 detects the signal as has been warped, such that the data is received. In another example, the inductor coils 104 may be modulated with the received signal, with the signal detector circuit 110 then detecting the signal as modulated.

More generally, different techniques can be used to send and receive data (i.e., signals). Such techniques include infrared transmission and detection, radio frequency transmission and detection, photonic transmission and detection, and electron and/or particle transmission and detection. In the infrared technique, infrared diodes, emitters, transmitters, and/or receivers may be employed. In the radio frequency technique, antennas, Helmholtz coils, microwave transmitters, and/or magnetrons may be employed. In the photonic technique, photo emitters, photoelectric diodes, pumped lasers, and/or laser diodes may be employed. In the electron and/or particle technique, particle accelerators, electron guns, magnetic lens, and/or electrostatic lens may be employed.

FIG. 2 shows a top view of the example omnidirectional communication device 100, in which the high voltage coils 106 and the inductor coils 104 are depicted in detail. As noted above, in the depicted example, the high voltage coils 106 are cylindrical. By comparison, in the depicted example, the inductor coils 104 are ring, loop, or toroidal in shape, as also noted above, but can instead be spherical.

The high voltage coils 106 includes a primary high voltage coil 106A and one or multiple secondary high voltage coils 106B. The high voltage coils 106 generate a high frequency electrostatic plasma field as the plasma field in question. An example of the voltage of the coils 106 is between 1 kilovolt and 12 million volts, and an example of the frequency of the resultant electrostatic plasma field is between 50 kilohertz and 10 gigahertz. The high voltage coils 106 can also be referred to as resonant transformers. The coils 106 may have a modulated driving circuit having a frequency range between 1 hertz and 60 gigahertz, if not higher. The coils 106 are tunable and can be driven at all frequency in the radio frequency domain. The driving circuit for the coils 106 may include or be connected to a signal detection circuit, an oscillator, a software-defined radio, an amplifier/rectifier, and/or a feedback circuit. In one implementation, the high voltage coils 106 may nevertheless be adjusted to accept low voltage alternating or direct current from 0.01 millivolts or higher if needed.

The primary high voltage coil 106A may be a helical coil, such as a helical resonator. The coil 106A may be an electromagnetic coil (i.e., a loading or primary coil) used as a radio wave resonator or filter, to induce voltage as well as signal into the inductor coils 104 as well as the secondary high voltage coils 106B. The primary high voltage coil 106A may have resonant inductive coupling with the secondary coils 106B, the inductor coils 104, and the central core 102. The helical resonator may include one coil or multiple coils, which can be single or multifilar, and which can be tunable to adjust the resonance, impedance and inductance. The shape of the coils may be cylindrical, spherical, toroidal, square or any other shape and can be arranged in various topologies. The helical resonator along with the secondary high voltage coils 106B make a series of resonant transformers that can send and receive signal from high voltage discharge. The secondary coils 106B coils can be arranged in various topologies and can form part of the circuits 108 and 110.

The gyroscopic electromagnetic fields generated by the inductor coils 104 within the central core 102 use the high frequency electrostatic plasma field generated by the high voltage coils 106. In the case of signal transmission, the high frequency electrostatic plasma field traps particles and anti-particles of the central core 102 for transmission by the electromagnetic fields, resulting in transmission of the signal. Helmholtz coils may be employed to create a penning trap to measure and trap particles within the device 100 for as long as possible. In the case of signal receipt, the high frequency electrostatic plasma field traps particles and anti-particles received by the central core 102 according to the signal, resulting in receipt of the signal.

The high voltage coils 106 can be wound around a framework that surrounds and supports the inductor coils 104 and the central core 102 in the center. The inductor coils 104 may be inductively coupled to the high voltage coils 106, electrically connected to a control circuit using slip rings, or by using rotary transformers. There may be feedback circuits connected to each coil 106 to collect data for processing and storage by a host computing device to which the communication device 100 is connected. Each high voltage coil 106 may be controlled via a corresponding high voltage coil circuit, specifically by controlling voltage and current applied to the coil 106 and by modulating bridge rectifiers of the coil 106.

The high voltage coils 106 may have an air core, an iron core, or another type of core, and can include single, double, or multiple high voltage discharge coils arranged in a variety of topologies. For example, in a cylindrical topology, the secondary coils 106B and top loads can be inserted around and/or into the top and bottom of the cavity of the communication device 100. The top load are metal spheres or toroids connected to the secondary coils 106b to attract the signal for feedback. The primary coil 106A can then be wound around the framework encompassing the entire structure of the cavity of the device 100 in a cylindrical shape.

As another example, in a spherical topology, primary and secondary coils 106A and 106B can be spherically mounted. The top loads can be pointed into the center of the cavity of the communication device 100 and/or inserted into the top and bottom of the cavity. The primary coil 106A can be wound around the framework encompassing the entire structure of the cavity of the device 100 in a spherical shape.

As a third example, in a toroidal topology, the secondary coils 106B and the top loads can be mounted around and/or into the top and bottom of the cavity of the communication device 100. The primary coil 106A can then be wound around the framework encompassing the entire structure of the cavity of the device 100 in a toroidal shape.

As a fourth example, in a circular topology, a series of top and bottom pillars of the secondary coils 106B and center top loads can be circularly spaced apart from one another around and/or in the cavity of the communication device 100. The primary coil 106A can then be wound around the framework encompassing the entire structure of the cavity of the device 100 in any shape.

As to the inductor coils 104, they can include an innermost inductor coil 104A, one or multiple middle inductor coils 104B around the innermost inductor coil 104A, and an outermost inductor coil 104C around the middle inductor coils 104B. The innermost inductor coil 104A is inductively or conductively connected (e.g., by parasitic or link induction) to the central core 102.

The middle inductor coils 104B generate a constantly changing electromagnetic flux as the electromagnetic fields. As such, the middle inductor coils 104 impart gyroscopic spin to the central core 102 via the innermost inductor coil 104A. The outermost inductor coil 104C supports the innermost inductor coil 104A and the middle inductor coils 104B, and is inductively or conductively connected to the high voltage coils 106.

The inductor coils 104 can be connected electrically and mounted concentrically, rotating inside of one another to vary inductance and strength of the electromagnetic fields. The inductor coils 104 may be controlled independently of one another or linked together. The inductor coils 104 may be motorized or non-motorized, and/or may be able to freely move independently.

The inductor coils 104 may be spun at the same speed or at different speeds, or may be stationary. The inductor coils 104 can spin for a specified amount of time, speed, and degrees of rotation. Electric motors and/or generators/alternators may be used in conjunction with the inductor coils 104 to ensure controlled spin, power/signal generation, and add torque to increase speed and overcome magnetic locking.

The inductor coils 104 can be toroidal in shape, or may have another shape. For example, the inductor coils 104 may be single ring, multiple ring, or spherical coils, as well as other shapes of coils. The inductor coils 104 can include circuits, laminated or coated conductor sheets, magnet wire, single wire conductor, and/or bifilar or multifilar wire. The inductor coils 104 can have an air or iron core, and be ferro fluid, liquid, or gas filled.

The inductor coils 104 can be core or air wound on a framework or be self-supported. If the coils 104 have a framework, the framework may be made from wood, metal, ferrites, crystals, silicon, plastics, rubber, foam, glass, reinforced concrete, ceramics, three-dimensionally (3D) printed material, cast material, or sintered material. The framework can thus include any material that a coil of wire can be wrapped around to give the resulting inductor coils 104 structure and strength.

FIG. 3 shows an example of the central core 102. The central core 102 can include one or multiple nested inductor coils 302 around a material 304. In the depicted example, the inductor coils 302 are spherical. The inductor coils 302 produce a consistent state of magnetic flux inside and outside of the core 102 to trap the electromagnetic fields impart by the inductor coils 104 (which are not to be confused with the inductor coils 302 of the core 102).

In the case of signal transmission, the inductor coils 302 vary the inductance and strength of the electromagnetic fields imparted by the inductor coils 104, specifically according to the signal injected by the signal injection circuit 108. Such variation causes collapse of the electromagnetic fields within the material 304 according to the signal. In turn, collapse of the electromagnetic fields transmits particles and/or anti-particles from the material 304 according to the signal, resulting in transmission of the signal.

In the case of signal receipt, the material 304 receives particles and/or anti-particles that have been transmitted according to a signal, which results in receipt of the signal. Receipt of the particles and/or anti-particles collapses the electromagnetic field within the material 304 according to the signal. This electromagnetic field collapse varies the inductance and strength of the electromagnetic fields, which can then be detected by the signal detector circuit 110, such that the detector circuit 110 detects the signal.

The inductor coils 302 of the central core 102 may be spherical or another shape. The inductor coils 302 may be wrapped around a framework, which may be or include a hermetically sealed shell including the material 304. The inductor coils 302 can be inductively or conductively connected to the inductor coils 104, and may be non-motorized or motorized to overcome magnetic locking or cogging.

The central core 102 is mounted concentrically within the inductor coils 104, and can be connected electrically to the inductor coils 104. The central core 102 can have movable axis points with varying degrees of rotation that are free to rotate or that can be positionally controlled around the axis of the inductor coils 104. For instance, motors, pins, slots, gears, rollers, skates, fixed connection points, bearings, and/or slew bearings may be employed in this respect.

The central core 102 rotates within the modulated high voltage plasma and gyroscopic electromagnetic fields produced by the high voltage coils 106 and the inductor coils 104. The position of the central core 102 within these fields varies the inductance and strength of the modulated electromagnetic field within the core. Such variation produces a collapse of the fields within the core, sending particles and/or anti-particles from the material 304, as noted above.

The central core 102 may be open air or encased within one or multiple hermetically sealed shells corresponding to the inductor coils 302, in which case the material 304 is encased within the innermost hermetically sealed shell corresponding to the innermost inductor coil 302. As one example, the hermetically sealed shells can be glass spheres. Except for the innermost shell that encases the material 304, the hermetically sealed shells can be filled with liquids, gases, fluids, or a vacuum. The central core 102 may also include a spark transmitter, ions, charged particles, and subatomic particles.

The material 304 may be different types of crystals, gases or plasmas, liquids, metals, and chemical elements. A non-exhaustive list of examples includes, for instance, silicon, quartz, ruby, fluorite/fluorine, calcite, selenite, galena, spin glass, time crystals, hydrogen, tritium, argon, neon, nitrogen, oxygen, krypton, xenon, helium, hydrogen peroxide, water, deuterium, gallium, cesium, rubidium, mercury, metal lattice confinement, iron, nickel, gold, aluminum, copper, tungsten, carbon, graphite, graphene, borophene, beryllium, and phosphorous. The material 304 ejects particles and/or anti-particles. These particles and/or antiparticles interact with the high voltage plasma in the gyroscopic electromagnetic fields generated by the inductor coils 104 and the high voltage coils 106, as noted above.

Adjacent to the material 304 within the innermost inductor coil 302 of the central core 102 may be circuits to impart various physical (i.e., mechanical), electrical, and other forces on the material 304. Depending on the type of material 304 in question, such devices can include motors, gyroscopes, flywheels, inductors, capacitors, super capacitors, magnetrons, electroacoustic transducers, lasers, ferrite beads, lattices, magnets, and electrodes. As an example of the latter, electrodes may be used to pulse voltage through the material.

As noted above, for signal transmission, the signal injection circuit 108 of the omnidirectional communication device 100 introduces a signal into the device 100 in accordance with data to be transmitted. The signal injection circuit 108 may be or include an electron beam to deliver electrons as the signal. As another example, the signal injection circuit 108 may be or include a particle accelerator to deliver charged particles as the signal. As a third example, the signal injection circuit 108 may be or include a photonic emitter to deliver photons as the signal.

As also noted above, for signal receipt, the signal detector circuit 110 of the omnidirectional communication device 100 detects the signal as has been warped, and therefore detects the data in accordance with which the signal has been transmitted to the device 100. The signal detector circuit 110 can include either or both of a piezoelectric detector circuit and a silicon detector circuit. The signal detector circuit 110 may additionally or instead detect electrons, charged particles, or photons received by the central core 102 as the signal.

An omnidirectional communication device 100 has been described that can omnidirectionally transmit and receive data over great distances. The communication device 100 achieves this via a central core 102, inductor coils 104 surrounding the central core 102, and high voltage coils 106. In the case of signal transmission, rotation of the central core 102 and the inductor coils 104 within the plasma field generated by the high voltage coils 106 warp the signal, which causes the central core 102 to omnidirectionally transmit the signal outside the device 100. In the case of signal receipt, the central core 102 receives an omnidirectionally signal transmitted from outside of the device 100, which is warped via rotation of the central core 102 and the inductor coils 104 within the plasma field generated by the high voltage coils 106, and then detected.

Furthermore, in different implementations, the device 100 can produce and utilize fusion energy in accordance with magnetic confinement, inertial electrostatic confinement, and/or magneto-inertial fusion. In this case, heat resistant materials can be used as frameworks for the coils 104 and/or 106 and the entire device 100 may be encased in a fusion reactor shell. Also the central core 102 may be or include a fusion reactor in this implementation. 

We claim:
 1. An omnidirectional communication device comprising: a central core to transmit a signal; inductor coils surrounding the central core to generate electromagnetic fields within and impart gyroscopic spin to the central core; high voltage coils to generate a plasma field within which the central core and the inductor coils rotate; and a signal injection circuit to introduce the signal into the device in accordance with data to be transmitted, wherein rotation of the central core and the inductor coils within the plasma field warp the signal, causing the central core to transmit the signal outside of the device.
 2. The omnidirectional communication device of claim 1, wherein the central core comprises one or multiple nested inductor coils around a material to produce a consistent state of magnetic flux inside and outside of the central core to trap the electromagnetic fields imparted by the inductor coil.
 3. The omnidirectional communication device of claim 2, wherein the one or multiple nested inductor coils vary an inductance and a strength of the electromagnetic fields according to the signal, wherein variation of the inductance and the strength of the electromagnetic fields collapses the electromagnetic fields within the material according to the signal, and wherein collapse of the electromagnetic fields transmits either or both of particles and anti-particles from the material according to the signal, resulting in transmission of the signal.
 4. The omnidirectional communication device of claim 2, wherein the material comprises one or multiple of: silicon, quartz, ruby, fluorite/fluorine, calcite, selenite, galena, spin glass, time crystals, hydrogen, tritium, argon, neon, nitrogen, oxygen, krypton, xenon, helium, hydrogen peroxide, water, deuterium, gallium, cesium, rubidium, mercury, metal lattice confinement, iron, nickel, gold, aluminum, copper, tungsten, carbon, graphite, graphene, borophene, beryllium, and phosphorous.
 5. The omnidirectional communication device of claim 1, wherein the inductor coils comprise: an innermost inductor coil inductively or conductively connected to the central core; one or multiple middle inductor coils around the innermost inductor coil to generate a constantly changing electromagnetic flux as the electromagnetic fields, imparting the gyroscopic spin to the central core via the innermost inductor coil; and an outermost inductor coil around the one or multiple middle inductor coils to support the innermost inductor coil, the one or multiple middle inductor coils, and the central core, and inductively or conductively connected to the high voltage coils.
 6. The omnidirectional communication device of claim 1, wherein the high voltage coils generate a high frequency electrostatic plasma field as the plasma field.
 7. The omnidirectional communication device of claim 6, wherein the high frequency electrostatic plasma field traps particles and anti-particles of the central core for transmission by the electromagnetic fields, resulting in transmission of the signal.
 8. The omnidirectional communication device of claim 1, wherein the signal injection circuit comprises an electron beam to deliver electrons as the signal.
 9. The omnidirectional communication device of claim 1, wherein the signal injection circuit comprises a particle accelerator to deliver charged particles as the signal.
 10. The omnidirectional communication device of claim 1, wherein the signal injection circuit comprises a photonic emitter to deliver photons as the signal.
 11. An omnidirectional communication device comprising: a central core to receive a signal transmitted from outside of the device in accordance with data; inductor coils surrounding the central core to generate electromagnetic fields within and impart gyroscopic spin to the central core; high voltage coils to generate a plasma field within which the central core and the inductor coils rotate, rotation of the central core and the inductor coils within the plasma field warping the signal; and a signal detector circuit to detect the signal as has been warped.
 12. The omnidirectional communication device of claim 11, wherein the central core comprises one or multiple nested inductor coils around a material to produce a consistent state of magnetic flux inside and outside of the central core to trap the electromagnetic fields imparted by the inductor coil.
 13. The omnidirectional communication device of claim 12, wherein the material receives either or both of particles and anti-particles according to the signal, resulting in receipt of the signal, and wherein receipt of either or both of the particles and the anti-particles collapses the electromagnetic fields within the material according to the signal.
 14. The omnidirectional communication device of claim 11, wherein central core comprises a material, the material comprising one or multiple of: crystals, gases or plasmas, liquids, metals, and chemical elements.
 15. The omnidirectional communication device of claim 11, wherein the inductor coils comprise: an innermost inductor coil inductively or conductively connected to the central core; one or multiple middle inductor coils around the innermost inductor coil to generate a constantly changing electromagnetic flux as the electromagnetic fields, imparting the gyroscopic spin to the central core via the innermost inductor coil; and an outermost inductor coil around the one or multiple middle inductor coils to support the innermost inductor coil, the one or multiple middle inductor coils, and the central core, and inductively or conductively connected to the high voltage coils.
 16. The omnidirectional communication device of claim 11, wherein the high voltage coils generate a high frequency electrostatic plasma field as the plasma field, and wherein the high frequency electrostatic plasma field traps particles and anti-particles received by the central core according to the signal, resulting in receipt of the signal.
 17. The omnidirectional communication device of claim 11, wherein the signal detector circuit comprises one or multiple of a silicon avalanche diode, a photodiode, a laser diode, a photomultiplier tube, a scintillator, an antenna, a photodetector, a magnetometer, a flat-panel detector, a microchannel plate detector, a magnetic pickup, an inductive sensor, a resonant coil antenna, an image sensor, an optical sensor, and a transducer.
 18. The omnidirectional communication device of claim 11, wherein the signal detector circuit detects electrons received by the central core as the signal.
 19. The omnidirectional communication device of claim 11, wherein the signal detector circuit detects charged particles received by the central core as the signal.
 20. The omnidirectional communication device of claim 11, wherein the signal detector circuit detects photons received by the central core as the signal. 